A power die package includes a lead frame having a flag with power leads on one lateral side and signal leads on one or more other lateral sides. A power die is attached to a bottom surface of the flag and electrically connected to the power leads with a conductive epoxy. A control die is attached to a top surface of the flag and electrically connected to the signal leads with bond wires. A mold compound is provided that encapsulates the dies, the bond wires, and proximal parts of the leads, while distal ends of the leads are exposed, forming a PQFN package.

In one example, a semiconductor device includes a substrate having leads that include lead terminals, lead steps, and lead offsets extending between the lead steps so that at least some lead steps reside on different planes. A first electronic component is coupled to a first lead step side and includes a first electronic component first side, and a first electronic component second side opposite to the first electronic component first side. A second electronic component is coupled to a second lead step side, and includes a second electronic component first side, and a second electronic component second side opposite to the second electronic component first side. An encapsulant encapsulates the first electronic component, the second electronic component, and portions of the substrate. The lead terminals are exposed from a first side of the encapsulant. Other examples and related methods are also disclosed herein.

A semiconductor device includes a semiconductor element, a support member, and a bonding layer interposed between the semiconductor element and the support member, wherein the bonding layer contains an alloy of first metal and second metal.

A semiconductor device includes: a semiconductor element; a support member; a bonding layer interposed between the semiconductor element and the support member; and a sealing resin that covers the semiconductor element and at least a portion of the support member, wherein the bonding layer is a layer in which a layer containing first metal and a layer containing second metal are integrated without going through a molten state, and wherein the support member includes a first surface facing in a thickness direction and facing a side on which the semiconductor element is located, and a plurality of first recesses located outside the bonding layer and recessed from the first surface when viewed along the thickness direction.

A method of manufacturing a semiconductor device, including: preparing a power semiconductor chip, a lead frame having a die pad part and a terminal part integrally connected to the die pad part, and an insulating sheet in a semi-cured state; disposing the power semiconductor chip on a front surface of the die pad part and performing wiring; encapsulating the lead frame and the power semiconductor chip with an encapsulation raw material in a semi-cured state, to thereby form a semi-cured unit, the terminal part projecting from the semi-cured unit, and a rear surface of the die pad part being exposed from a rear surface of the semi-cured unit; pressure-bonding a front surface of the insulating sheet to the rear surface of the semi-cured unit to cover the rear surface of the die pad part; and curing the semi-cured unit and the insulating sheet by heating.

In examples, a wafer chip scale package (WCSP) comprises a semiconductor die including a device side having circuitry formed therein. The WCSP includes a redistribution layer (RDL) including an insulation layer abutting the device side and a metal trace coupled to the device side and abutting the insulation layer. The WCSP includes a conductive member coupled to the metal trace, the conductive member in a first vertical plane that is positioned no farther than a quarter of a horizontal width of the semiconductor die from a vertical axis extending through a center of the semiconductor die. The WCSP includes a lead coupled to the conductive member and extending horizontally past a second vertical plane defined by a perimeter of the semiconductor die.

In one example, a semiconductor device comprises a substrate having a top surface and a bottom surface, an electronic device on the bottom surface of the substrate, a leadframe on the bottom surface of the substrate, the leadframe comprising a paddle, wherein the paddle is coupled to the electronic device, and a lead electrically coupled to the electronic device. The semiconductor device further comprises a first protective material contacting the bottom surface of the substrate and a side surface of the electronic device.

A semiconductor device module includes an application board, a plurality of semiconductor device packages disposed on the application board, each one of the semiconductor device packages including a semiconductor die, a leadframe including a plurality of leads, the leads including a spring support and a heat dissipation element, and an encapsulant embedding the semiconductor die and first portions of the leads, an external heatsink, and one or more thermally conductive interface layers disposed between the semiconductor device package and the heatsink.

According to an aspect, a semiconductor package includes a substrate having a first surface and a second surface opposite to the first surface, a semiconductor die coupled to the second surface of the substrate, and a molding encapsulating the semiconductor die and a majority of the substrate, where at least a portion of the first surface is exposed through the molding such that the substrate is configured to function as a heat sink.

A power semiconductor apparatus includes a mold portion, a panel that is conductive and in a flat plate shape, and a plurality of fins. The mold portion includes a power semiconductor element and a base plate that are molded. An opening is formed in the panel into which the base plate is inserted. The plurality of fins is fixed in grooves of the base plate. The panel has a plurality of protrusions on side surfaces forming the opening. Each protrusion has a fifth surface a cross section of which has a shape that tapers down toward an end of the protrusion, the cross section being parallel to a plane extending in the Z direction and a direction in which the protrusion protrudes. The base plate has cover portions covering the fifth surfaces, and is plastically deformed to allow the panel to be fitted in the base plate to fill gaps.